Skin-heating shaving apparatus and method

ABSTRACT

A shaver that includes a cartridge with one or more razor blades and a source of RF energy operative to apply RF energy to one or more of the blades. The cartridge can be attached to a handle for moving the cartridge along the surface of the skin. The cartridge may include a variety of configurations including one or more electrodes and one or more blades with the RF current conducting through any subset of the electrodes and blades, through the skin, thereby heating the skin to help facilitate the engagement of the blade with the hair on the skin surface.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is related to and incorporates by reference U.S. patentapplication Ser. No. 12/324,932 filed on Nov. 28, 2008.

TECHNICAL FIELD

The method and apparatus relate to shaving razors and in particular torazors operative to apply RF heating energy to skin during shaving.

BACKGROUND

Several attempts have been made in the art to reduce the discomfort andirritation resulting from shaving while still allowing for a closeshave, i.e. leaving a hair stub as short as possible, preferably havingthe remaining hair shaft tip rest inside the hair follicle, so that theshaved skin is smooth to the touch.

Multiple blade cartridges, fixed to, or pivot about their handle, suchas Gillette brand Sensor Excel™ series, employ the hairpulling-and-cutting process. The process includes a set of “resilientlymounted elements” such as that described in U.S. Pat. No. 5,802,721 or ablade which lifts the hair up, pulling it as far out of the skinfollicle as possible, so that the cutting operation is performed by asucceeding blade on the part of the hair that is, when relaxed, belowthe surface of the skin. This process may sometimes be associated withdiscomfort resulting from the stiffness of the hairs and the tuggingapplied to the hair shaft that is strongly attached to the follicle inwhich it is situated.

In an attempt to minimize the discomfort resulting from the pulling andcutting process, it has become common practice to heat the razor bladesand/or facial skin with hot water so as to soften the hair bristles.Shaving creams, gels and lotions have also been developed for the samereason.

Some shaving devices known in the art set out to reduce the discomfortof pulling-on and cutting stiff hairs by heating the device itself. Theidea shared by most is heating the cartridge blades employing meansother than rinsing with hot water. United States patent application2006/0117568 describes pre-heating of the razor cartridge prior toshaving and relying on heat conduction to warm the blades. Other shavingdevices, such as that described in U.S. Pat. No. 6,836,966 and U.S. Pat.No. 6,817,101, electrically heat the blades themselves in an attempt tosoften the hair shafts.

BRIEF SUMMARY

In accordance with one exemplary embodiment of the current method andapparatus, a shaver is provided having a cartridge including one or morerazor blades and a source of RF energy operative to apply RF energy toone or more of the blades. Further, such embodiment may include a handlethat can be held or gripped to enable maneuverability of the cartridgeover the surface of the skin. The one or more blades are operative tocouple the RF energy to the skin.

Applying RF energy to the skin operates to heat the skin, soften thehair shaft and in some cases affect the hair follicle so that to reducethe discomfort resulting from the stiffness of the hairs and thetugging. Advantageously, these characteristics help to make the shavingprocess more pleasant and soothing from the perspective of a user and,to provide a closer shave with minimal irritation to the skin.

In accordance with another embodiment of the current method andapparatus the cartridge includes one or more razor blades and one ormore RF electrodes.

Acne is one of the most common skin disorders and is affecting millionsof people. In accordance with yet another embodiment of the currentmethod and apparatus, the heat generated at deeper levels of the skin,such as at the level of the dermis, for example, is sufficient toinactivate Propionibacterium acnes (P. acnes) bacteria commonly locatedtherewithin, thus assisting in the healing process of existing facialacne and preventing future development thereof.

Optionally, in accordance with still another embodiment of the currentmethod and apparatus, the cartridge may also include one or more bladesconstructed of a high electrical—resistance material that may generateadditional heat when necessary. The cartridge may also include a heatsensor, such as a thermistor and an electronic control to control and/orregulate the temperature of the skin, blades or electrodes. The heatsensors may be located on the cartridge itself, blades and/orelectrodes.

The blades may also be coated with one or more types of coating such asa protective coating, thermally conductive coating, hardness increasingcoating, dielectric coating and a coating reducing blade friction.

In accordance with another embodiment of the current method andapparatus the blades may be cooled by a heat sink or other cooling meansto protect the surface of the skin when heating deeper layers thereof.This results in the heat generated by the RF energy in the skin to bespecifically directed, if so desired, at the level of the hair folliclesin addition to softening the hair shafts or any other desired level.Additionally or alternatively the heat generated by the RF energy in theskin may be specifically directed at the collagen layer bringing aboutstimulation and growth thereof. These applications of RF energy to theskin of the user (and in particular to the facial area.) may alsocontribute to changes in deeper skin layers that may bring about wrinklereduction, tightening of the skin and an overall enhanced comfort duringshaving.

It will be appreciated that the energy applied by the aforementionedelectrodes may be replaced by other heat energy generating means such aslight energy, ultrasound energy and others.

BRIEF DESCRIPTION OF THE DRAWINGS

The present method and apparatus will be understood and appreciated fromthe following detailed description, taken in conjunction with thedrawings in which:

FIG. 1 is a simplified illustration of a shaving apparatus constructedand operative in accordance with an exemplary embodiment of the presentapparatus and method;

FIGS. 2A, 2B, 2C, 2D, 2E and 2F are simplified cross-sectional viewillustrations of four exemplary embodiments of current method andapparatus;

FIG. 3A is a simplified elevated oblique view and sectionalcross-section view illustration of another exemplary embodiment of thecurrent method and apparatus;

FIG. 3B is a simplified cross-sectional view illustration of the shavingapparatus of FIG. 3A as viewed in the direction indicated by arrow (V);

FIGS. 4A, 4B, 4C, 4D and 4E are simplified elevated oblique view anddropped oblique view and cross-sectional view illustrations of threeadditional exemplary embodiments of the shaving apparatus of the currentmethod and apparatus;

FIGS. 5A, 5B and 5C are simplified illustrations of yet anotherexemplary embodiment of the current method and apparatus; and

FIG. 6 is a simplified elevated oblique view and cross-sectional viewillustration of another embodiment of the current method and apparatus.

DETAILED DESCRIPTION

The term “Skin”, as used in the present disclosure, means all layers ofskin including the epidermis, dermis including all dermal structuressuch as hair follicles, blood vessels, collagen tissue and the fatlayer.

Reference is now made to FIG. 1, which is a simplified illustration of ashaving apparatus constructed and operative in accordance with anexemplary embodiment of the present apparatus and method. A shavingapparatus 100 includes a handle 110 that can be held or gripped and areusable or disposable cartridge 120 that can be attached, coupled,joined, and/or connected, and sealed to the handle 100 in such a way asto prevent penetration of water into the handle, but that can also beremoved again from the handle.

The handle 110 includes or houses a source of energy 112 operative tosupply energy to an RF generator 114, which, in turn, supplies RF energyto the components in cartridge 120, such as RF coupling blades,electrodes, gel dispenser heating elements 420 (FIGS. 4D and 4E) etc.The level and duration of the RF energy supply to cartridge 120components is controlled by a control circuit 116. Control circuit 116may be operational intermittently upon demand, such as (a) a press-ablebias-countered switch, (b) an adjustable type control to adjust thelevel of desired RF power output or (c) a standard on-off type switch asknown in the art. The handle 110 also includes terminals 118 located atthe attachable tip thereof, which come in contact with correspondingterminals 128 located at the attachable portion on cartridge 120 uponattachment thereof to handle 110. The RF power may be generated incontinuous or pulse form, a variation or combination of both, and canvary in the range in the amount or duration of the continuous power, orthe duty cycle and frequency of the pulsed power.

In another embodiment of the current method and apparatus, either one orboth of power source 112 and RF generator 114 may be located externallyto handle 110 and supply the power or RF signals to the handle 110through an electrical cord (not shown). Control circuit 116 in thisembodiment may be located on handle 110 or on a housing (not shown) inwhich power source 112 and/or RF generator 114 may be located.

Cartridge 120 may include, among other components, one or more blades, apair of which 122 is presented in FIG. 1. Cartridge 120 may bedisposable in part or en-bloc. Blades 122 are positioned in parallel toeach other and are operative to cut hair and couple RF energy to theskin while translating cartridge 120, employing handle 110, in astroking motion over the skin to be shaved. Blades 122 may be suppliedwith RF energy from RF generator 114 of handle 110 with which theyelectrically communicate through terminals 128 and 118.

In an exemplary embodiment of the current method and apparatus theelectrical wiring of blades 124 and 126 may be configured as depicted inFIG. 1 so that blades 124 and 126, when supplied with RF energy from RFgenerator 114 create an RF current that flows between the blades, aswill be explained in further detail below. In other exemplaryembodiments of the current method and apparatus either one, or both, ofblades 124 and 126 may be replaced by an RF electrode.

Blades 124 and 126 may also be coated with one or more types of coatingsuch as a protective coating, thermally conductive coating, hardnessincreasing coating, dielectric coating and/or a coating that reduces theblade friction. Additionally or alternatively, blades 124 and 126 may beconstructed of a highly electrical resistance material to enable theblades to generate heat when a current is passed through the blades.

In accordance with yet another embodiment, blades 124 and/or 126 mayalso include a thermistor 130 to monitor and/or control and/or regulatethe temperature of the skin being shaved.

Turning now to FIGS. 2A and 2B, which are simplified cross-sectionalview illustrations of two exemplary embodiments of the current methodand apparatus. FIG. 2A illustrates a double blade configuration in whichreusable or disposable cartridge 200 includes blades 224 and 226,operative to couple RF energy to skin 202 to be shaved. Blades 224 and226, when supplied with RF energy, create a current 204 that flows fromone blade, through skin 202 and to the other blade. Current 204 causesthe heating of a skin portion 206 that, for purposes of this exemplaryembodiment only, is located in the dermis layer of skin 202 at the levelof, and including but not limited to, hair follicle 208 and hair 210.The heat generated in skin portion 206 of skin 202 softens hair shaft210 making it more amenable to cutting by blade 224 when cartridge 200is translated over the skin in the direction depicted by arrow 280.Additionally, applying RF energy to skin 202 sometimes allows detachmentof the hair shaft 210 from follicle 208 as well as affecting thefollicle itself in some cases.

The depth (d) of heated portion 206 from the surface of the skin may bedetermined by the level of RF power coupled by blades 224 and 226 andthe distance (L) between the two blades. For example, at a given RFsetting, the depth (d) of heated portion 206 is approximately half ofthe distance (L) between blades 224 and 226. However, those skilled inthe art will appreciate that this ratio can vary depending on a varietyof factors including the material used in the blades, the frequency ofthe RF energy, the type of skin and the chemical composition of the skinas well as materials (lotions, sweat, water, etc.) on the surface of theskin 202. Assuming, for purpose of example only, that the thickness ofskin 202 to be shaved is approximately 1.8 mm, to achieve heating ofhair follicles 208 in skin 202, the desired center of heated portion 206should be located at an approximate depth (d)=of 0.9 mm. This requirespositioning blades 224 and 226 with a distance (L)=1.8 mm between theblades. The depth of heated segment 206 may, when so desired, alsoaffect the sub-cutaneous fatty tissue layer (not shown). In general, thehigher the level of RF power coupled to the skin—the higher theresulting temperature of heated portion 206. Heat effected in the centerof portion 206 is carried outward in a radial fashion by conduction,heating adjoining portions and enlarging the volume of portion 206.

Shaving other areas of the body having thicker skin resulting from athick dermis layer or deeper collagen layer may require readjusting thelevel of coupled RF energy or the distance between blades 224 and 226.The coupled RF power levels may range from, but not be limited to, 1-20Watts. The RF frequency may range from, but not be limited to, 300 kHzto 10 Mhz.

The heat generated by coupled RF energy to skin 202 may bring aboutadditional beneficial changes in the tissue, such as the breakdown ofcollagen fibers in the dermis and stimulation of collagen tissueresulting in wrinkle reduction, tightening of the skin as well asoverall enhanced comfort during shaving.

In another embodiment of the current method and apparatus the level ofheat generated by coupled RF energy to skin 202 may be selected to reacha temperature in a range known to deactivate Propionibacterium acnes (P.acnes) bacteria, the cause of facial acne. It has been demonstrated thatthe application of heat at various time and temperature combinationsreliably deactivates the P. acnes bacteria. The necessary temperaturerange to deactivate the P. acnes bacteria is generally above 47 degreesCelsius, but below the burn or discomfort threshold for human skin.Depending on the area of skin and the area of surface contact, the upperdiscomfort threshold is in the range of 51 degrees Celsius. Hence,coupling RF energy employing a relatively rapid, transient applicationsuch as shaving strokes may bring about transient heating of skin 202portion 206, to temperatures necessary to deactivate P. acnes bacteriawithin the portion 206. Additionally, heating the skin also increasesthe blood circulation in the heated area. This not only assists in thehealing process of existing facial acne but may also assist inpreventing future acne development since P. acnes is a common resident(commensal) in human skin. Cooling the surface of the skin, as will bedescribed in greater detail below, may increase tolerability toincreased P. acnes bacteria deactivation temperatures in the skin ingeneral and in deeper layers specifically.

Referring now to FIG. 2B, which is a simplified cross-sectional viewillustration of another exemplary embodiment of the shaving apparatus ofFIG. 1. In this embodiment, blade 226 of FIG. 2A is replaced byelectrode 236, which may be an RF electrode. Electrode 236 may berounded, coated with a smooth-surface material, in a form of a roller orin any other form which enables electrode 236 to be operative totranslate smoothly over the surface of the skin.

Referring now to FIGS. 2C, 2D and 2E which are simplifiedcross-sectional view illustrations of yet another exemplary embodimentof the current method and apparatus. FIG. 2C depicts a cartridge 200including 2 blades 224 and 226 and an electrode 236. Alternatively,electrode 236 may be replaced by a blade and either one of blades 224and 226 may be replaced by an RF electrode. The distance between blade226 and electrode 236 is selected to generate the heating of portion 206of skin 202 and hair follicle 208 as described hereinabove. The distancebetween blades 224 and 226 is selected to enable the engagement withhair on the skin surface, such as the pulling the hair, cutting thehair, and/or the pulling-and-cutting process as employed by Gillettebrand Sensor Excel™ series and other multiple blade shaving cartridgesand as described in U.S. Pat. No. 5,802,721. In FIG. 2C, RF energy iscoupled to skin 202 generating heat in heated portion 206 heating hairfollicle 208 and hair shaft 210. This softens hair shaft 210 making thehair more prone to be cut or removed. FIG. 2D depicts translation ofcartridge 200 over the surface of the skin in a direction depicted byarrow 280. At this stage, coupling of RF energy to skin 202 may cease(e.g., in RF pulse mode) or be applied continuously to go on heatinganother portion of skin. Blade 226 catches hair shaft 210 and partiallypulls it out of follicle 208. At this point in time, hair shaft 210 maybe softer and its attachment to follicle 208 more resilient, having beenheated by RF energy coupled thereto, making hair shaft 210 readilymovable within follicle 208. This further reduces the pain anddiscomfort associated with the shaving process. FIG. 2E illustratesfurther translation of cartridge 200 over the skin in the directiondepicted by arrow 280 bringing about cutting of the now softened andpulled hair shaft 210 by blade 224. Alternatively, the temperaturereached within heated portion 206 may sometimes bring about changes infollicle 208 resulting in easier removal of hair shaft 210 upon pullingthereof from follicle 208 at the stage depicted by FIG. 2D.

The temperature achieved in the skin and over the surface thereof andthe amount of resistance of the hair to pulling and detachment from thehair follicle may be dependent not only on the type of electrode, typeof applied charge wave (i.e., pulsed or continuous), level and durationof the RF voltage and distance between the electrodes, but also on thespeed of translation of cartridge 200 over the skin.

Referring now to FIG. 2F, which is a simplified cross-sectional viewillustration of yet another exemplary embodiment of current method andapparatus. In this embodiment, cartridge 200 includes two marginallylocated electrodes 236 and having blades 224 and 226 located between theelectrodes. In this configuration, blades 224 and 226 may be rotatingblades such as those employed by electrically motorized shaving devices,standard blades, reciprocating blades, vibrating blades, etc.

Turning now to FIG. 3A, which is a simplified elevated oblique view andsectional cross-section view illustration of another exemplaryembodiment of the current method and apparatus. Reusable or disposablecartridge 300 includes blades 324 and 326 and supporting dividers 330positioned between the blades. FIG. 3B depicts a cross section ofcartridge 300 of FIG. 3A at the level of blade 324 along axis Y-Y andviewed in the direction indicated by arrow (V). In this exemplaryembodiment, blades 324 and 326 (not shown) are regular razor blades.Dividers 330 may be RF electrodes, or alternatively include RFelectrodes on internal walls 330 a and 330 b thereof, and electricallycommunicate with RF generator 114 of handle 110 (FIG. 1).

The distance between adjacent dividers 330 may be predeterminedaccording to the desired depth of heated portion 206 in skin 202 andlevel of coupled RF power as explained in detail hereinabove. Applyingcartridge 300 against the skin to be shaved, urges the surface 302 ofskin 202 against lip 328 of dividers 330, creating effective contactbetween the skin 202 and the dividers 330.

Coupling RF energy to skin 202 increases the temperature of the surfaceof the skin as well as the temperature of deeper skin tissue layers suchas the dermis, the structures within the skin, and collagen layer asdescribed hereinabove. Cooling the surface of the skin may increase thetolerance to the elevated temperature in the deeper layers and enhancethe comfort of the shaving experience.

Turning now to FIGS. 4A and 4B, which are simplified elevated obliqueview illustrations of an additional exemplary embodiment of the currentmethod and apparatus. In FIG. 4A, which is a partially exploded view inwhich a blade cover portion 402 of a reusable or disposable cartridge400 is raised for illustration purposes only to expose blade 424. Blade424 may be forged with a multiplicity of projecting fins 404 constructedof a heat conducting material such as, but not limited to, copper oraluminum alloys and creating a heat sink 406 operative to dissipate heatconducted to blade 424 from the surface of the skin heated by RF energy.

Alternatively and additionally, blade 424 and heat sink 406 may becoated with a thermally conductive electrically insulating resin. Inaccordance with still another embodiment of the current method andapparatus, blade cover portion 402 may be made of a thermally conductivematerial embedding heat sink 406 when in place and attached to blade424. FIG. 4B illustrates another embodiment of the current method andapparatus in which cartridge 400 further includes a conductive, coolingand hair softening gel dispenser 408 for dry skin shaving. Conductive,cooling and hair softening gel may be stored inside dispenser 408 and beapplied to the skin through pores, openings, roller balls, or otherapplicators 410 at the application surface 412 thereof. Applicationsurface 412 may be constructed of a semi-flexible material so that thegel may be applied through pores or openings 410 upon light squeezingpressure on dispenser 408 resulting from the pressing of cartridge 400against the skin to be shaved.

Alternatively, the conductive, cooling and hair softening gel may bestored in a compartment (not shown) in handle 110 (FIG. 1) having aresilient wall and communicating through a dedicated detachable tubesystem with dispenser 408 and dispensed upon squeezing pressure appliedto the gel compartment resilient wall by the user. Alternatively andadditionally, the embodiments depicted in FIGS. 4A and 4B may becombined to add to the cooling effect of the gel to that of heat sink406.

In FIG. 4C, which is a partially exploded dropped oblique view in whichdispenser 408 is removed for illustration purposes only to expose blade426. Blade 426 may be forged with a multiplicity of projecting fins 404such as those depicted in FIG. 4A, constructed of a heat conductingmaterial such as, but not limited to, copper or aluminum alloys andcreating a heat sink 406. The heat conducted to blade 424 from thesurface of the skin in this embodiment is conducted through blade 426and heat sink 406 and heats the gel inside dispenser 408 (when attached)sufficiently to expand the volume of the gel urging it out through poresor openings 410. Alternatively, as depicted in FIGS. 4D and 4E, whichare cross sectional view illustrations of FIG. 4B taken along axis T-T,dispenser 408 may include a first larger gel chamber 414 containing gel428 and a second smaller fluid chamber 416 with a resilient divider 418between the two chambers. Fluid chamber 416 further comprises heatingelectrodes 420, supplied by power source 112 in handle 110 and a fluid438 with a high expansion coefficient. When switch 116 is activated, italso activates heating electrodes 420 that heat fluid 438 bringing aboutthe boiling thereof creating a bubble 440. The expansion of bubble 440in the direction indicated by the arrows urges against resilient divider418 urging gel 428 out through pores or openings 410. The gel may be anywater-based conductive gel, lubricant, moistener, etc. known in the art.

Referring now to FIG. 5A, which is a simplified elevated oblique viewand sectional cross-section view illustration of another exemplaryembodiment of the current method and apparatus. A reusable or disposablecartridge 500 includes blades 524 and 526 and supporting dividers 530positioned between the blades. Additionally, cartridge 500 also includesa lip 502 that serves as an electrode carrier 504 for a multiplicity ofRF voltage-applying dome-shaped elements 506 protruding from the surfacethereof of the type described in assignee's above-incorporated byreference Patent Application No. WO2009/072108 and U.S. patentapplication Ser. No. 12/324,932.

Elements 506 may be arranged in lengthwise arranged rows 508 a, 508 b,508 c and 508 d arranged along axes parallel to axis W-W. The electricalwiring of elements 506 may be configured to apply a current between allelements 506 sharing the same row and all elements 506 sharing anadjacent row. For example, an RF current may be applied between allelements sharing row 508 a and all elements sharing row 508 b andbetween all elements sharing row 508 c and all elements sharing rows 508d. Since the depth of heated portion 206 in skin 202 is influenced bythe distance between the electrodes and the current between them, thedetermination of which rows to apply RF energy to may depend on thedesired depth of heated portion 206. This configuration is illustratedby FIG. 5B, which is a cross section of lip 502, carrier 504 andelements 506 in FIG. 5A taken along the axis Z-Z.

In accordance with yet another embodiment of the current method andapparatus, elements 506 may be arranged in crosswise arranged rows 510(marked for the purpose of clarity by broken lines) arranged along axesparallel to axis Z-Z and wherein the electrical wiring of elements 506applies a current between each pair of adjacent elements 506 sharing thesame row. This configuration is illustrated by FIG. 5C, which is a crosssection of carrier 504 and elements 506 in FIG. 5A taken along the axisW-W.

In accordance with still another embodiment of the current method andapparatus, any one of blades 524 or blade 526 may be operative to coupleRF energy to skin or be replaced by an RF electrode. A current may beapplied between all, a single row or multiple rows of elements 506 oncarrier 504 and blade 524 or 526. It will be appreciated that thedistance between elements 506 and blade 524 or 526 will determine thedepth of heated portion 206 of skin 202 from the surface thereof.Voltage may be applied, for example, between all, a single row ormultiple rows of elements 506 on carrier 504 and blade 526. Thisconfiguration is similar to the configuration depicted in FIGS. 2C, 2Dand 2E. Additionally, electrode carrier 504 may also include athermistor 512 being in contact with the surface of skin 202 for skintemperature control. It will also be appreciated that a series ofswitches may be included in the control circuitry so that theapplication of the RF energy can be dynamically changed and controlledduring the use of the device. For instance, the switches can be open orclosed thereby changing the flow of the RF energy between the variouselectrodes and blades. Such control can be random, sequenced, based onfeedback, or any of a variety of other criteria.

Turning now to FIG. 6, which is a simplified elevated oblique viewillustration of another embodiment of the current method and apparatus.A reusable or disposable cartridge 600 includes one or more thermistors602 which may supply feedback to circuit controller 116 to modify RFenergy application in accordance with the temperature of the skinsurface and to avoid overheating of the skin thus contributing to thesafety and comfort of shaving. FIG. 600 depicts several possiblelocations for placing such thermistors 602, such as on blades 624 and/or626, sidewalls of divider 630 as designated by reference numeral 602 aor along lip 628 of dividers 630 as designated by reference numeral 602b to make contact with the surface of skin 202 while shaving.Additionally or alternatively, thermistors 602 may also be placed in anyother desired suitable location.

In an exemplary embodiment, a controller/charger base may be includedwith the shaving apparatus. In such an embodiment, the control of the RFcircuitry and the charging of batteries within the shaving apparatus maybe incorporated into the base. The base and the shaver may include awireless communication means, such as BLUETOOTH for providing control ofthe RF control and/or receiving feedback from the thermistors, batterylevel, etc. For example, in such an embodiment, the base may be used toreceive temperature feedback from one or more thermistors and, thenprovide control of the application of RF energy by sending controlcommands to the shaving device.

It will be appreciated that the energy applied by the aforementionedelectrodes may be replaced in the future by other heating energygenerating means such as laser energy, ultraviolet (UV) commonly used intreatment of acne, ultrasound energy, and others.

It will also be appreciated by persons skilled in the art that thepresent method and apparatus are not limited to what has beenparticularly shown and described hereinabove. Rather, the scope of themethod and apparatus includes both combinations and sub-combinations ofvarious features described hereinabove as well as modifications andvariations thereof which would occur to a person skilled in the art uponreading the foregoing description and which are not in the prior art.

What is claimed is:
 1. A shaving apparatus, said apparatus comprising: acartridge to be applied to the skin including at least one blade; asource of RF energy operative to supply RF energy to said blade; and ahandle that can be coupled to said cartridge and operative to enable thetranslation of said cartridge over the skin such that at least one bladeis operative to couple RF energy at a frequency in the range of 300 KHzto 10 MHz to the skin and engage hair on the surface of the skin duringshaving.
 2. The apparatus according to claim 1, wherein said cartridgecomprises at least two blades arranged in parallel orientation to eachother.
 3. The apparatus according to claim 2, wherein the two bladescouple RF energy to the skin.
 4. The apparatus according to claim 2,wherein at least one of said blades includes a temperature sensor. 5.The apparatus according to claim 2, wherein said cartridge furthercomprises a temperature sensor operative to contact the surface of theskin.
 6. The apparatus according to claim 5, wherein said sensor islocated between said blades.
 7. The apparatus according to claim 1,further comprising at least one power supply operative to power saidsource of RF energy and heat said blades.
 8. The apparatus according toclaim 1, wherein said cartridge is a disposable cartridge.
 9. A shavingapparatus, said apparatus comprising: a cartridge to be applied to theskin including at least one blade operative to engage with hair on theskin and at least one electrode operative to couple RF to a targetsegment of the skin; a source of RF energy coupled to and operative tosupply RF energy to the skin during shaving at a frequency in the rangeof 300 KHz to 10 MHz to said electrode; and a handle attachable to saidcartridge and operative to enable the translation of said cartridge overthe skin.
 10. The apparatus according to claim 9, further comprising atleast two electrodes and wherein the at least one blade is locatedbetween the electrodes, the electrodes and at least one blade arrangedwithin the cartridge to be applied to the skin and are in parallel toeach other.
 11. The apparatus according to claim 9, further comprisingat least two electrodes and wherein said cartridge further comprises atemperature sensor located between said electrodes and operative tocontact the surface of the skin.
 12. The apparatus according to claim 9,wherein said at least one blade includes a temperature sensor.
 13. Theapparatus according to claim 9, wherein said at least one said electrodeincludes a temperature sensor.
 14. The apparatus according to claim 9,further comprising at least one power supply operative to power saidsource of RF energy and heat the blades.